Influence of state and crystallinity of lipid matrix on physicochemical properties and permeation of capsaicin-loaded lipid nanoparticles for topical delivery

Abstract

The purpose of this study was to evaluate the influence of crystallinity and state of lipid matrix on the physicochemical properties and in vitro skin permeation of capsaicin-loaded lipid nanoparticles. Capsaicin-loaded SLN were prepared from Dynasan 116 and Softisan 378 and their physicochemical properties were investigated and compared with a nanoemulsion prepared from Miglyol 812. The mean particle sizes of all lipid nanoparticles were in the range of 160–340 nm with the PDI between 0.10 and 0.25. From DSC data, capsaicin was dissolved or molecularly dispersed in lipid matrix of nanoparticles and Dynasan 116 SLN was in the crystalline state whereas Softisan 378 SLN remained in supercooled melts. The occlusion factor was influenced by crystallinity and state of lipid matrix. The physical stability of capsaicin-loaded SLN and NE hydrogel strongly depended on storage temperature and emulsifiers. The percentage of capsaicin after stored for 6 months was in the range of 90–110%, regardless of studies storage temperature. The in vitro skin permeation revealed that the amount of capsaicin permeated through epidermis related to the state of lipid matrix and crystallinity. The solid state with high crystallinity and occlusion factor provided the greater skin permeation whereas the supercooled melts behaved like the nanoemulsions.